Imaging device and imaging system

ABSTRACT

An object of the present invention is to prevent a sensitivity difference between pixels. There are disposed plural unit cells each including plural photodiodes  101 A and  101 B, plural transfer MOSFETs  102 A and  102 B arranged corresponding to the plural photodiodes, respectively, and a common MOSFET  104  which amplifies and outputs signals read from the plural photodiodes. Each pair within the unit cell, composed of the photodiode and the transfer MOSFET provided corresponding to the photodiode, has translational symmetry with respect to one another. Within the unit cell, there are included a reset MOSFET and selecting MOSFET.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to imaging devices and imaging systems,and more particularly to an imaging device having disposed thereinplural unit cells including plural photoelectric conversion regions,plural transfer switch means provided corresponding to the pluralphotoelectric conversion regions, respectively, and common amplificationmeans which amplifies and outputs signals read from the pluralphotoelectric conversion regions.

2. Related Background Art

In recent years, imaging devices called a CMOS sensor using CMOS processare attracting attention. By virtue of integratability of peripheralcircuitry, low-voltage drive, and so on, the CMOS sensor is beingincreasingly applied particularly to the field of mobile informationdevices.

As a pixel configuration of CMOS sensors with a high. S/N ratio, forexample, there has been known one in which a transfer switch is disposedbetween a photodiode and the input of a pixel amplifier as disclosed inJapanese Patent Application Laid-Open No. H11-122532. However, thedrawbacks of this pixel configuration include a fact that since thenumber of transistors is large, when the pixel is scaled down, it isdifficult to secure a sufficient area for the photodiode underconstraint of the area required for the transistor. In order to overcomethis disadvantage, there has recently been known a configuration inwhich plural adjacent pixels share a transistor, as disclosed, forexample, in Japanese Patent Application Laid-Open No. H09-046596(corresponding to U.S. Pat. No. 5,955,753). FIG. 12 (identical to FIG. 8in the same patent application) shows the imaging device of conventionalart. In the drawing, reference numeral 3 denotes a transfer MOStransistor acting as a transfer switch; 4 a reset MOS transistor whichsupplies a reset potential; 5 a source-follower MOS transistor; 6 ahorizontal selecting MOS transistor for selectively allowing thesource-follower MOS transistor 5 to output a signal; 7 a source-followerload MOS transistor; 8 a dark output transfer MOS transistor fortransferring a dark output signal; 9 a bright output transfer MOStransistor for transferring a bright output signal; 10 a dark outputaccumulation capacitor CTN for accumulating the dark output signal; 11 abright output accumulation capacitor CTS for accumulating the brightoutput signal; 12 a horizontal transfer MOS transistor for transferringthe dark output signal and bright output signal to a horizontal outputline; 13 a horizontal output line reset MOS transistor for resetting thehorizontal output line; 14 a differential output amplifier; 15 ahorizontal scanning circuit; 16 a vertical scanning circuit; 24 anembedded photodiode. Here, the dark output signal is a signal generatedby resetting the gate region of the source-follower MOS transistors 5;the bright output signal is a signal obtained by combining a signalobtained by photoelectric conversion using the photodiode 24 and thedark output signal. From the differential output amplifier, there isobtained a signal with reduced fluctuation of the source-follower MOStransistor 5.

As evident from the drawing, one source-follower MOS transistor 5 isconnected to two photodiodes 24 disposed in a vertical direction viatransfer MOS transistors 3. Accordingly, while eight MOS transistors arerequired for two pixels in the conventional art, it is sufficient toprovide five MOS transistors, thus being advantageous inminiaturization. By sharing the transistor, the number of transistorsper pixel is reduced, whereby the area for the photodiode can besufficiently secured.

Also, as an exemplary pixel layout of the shared-transistorconfiguration, there is one disclosed in Japanese Patent ApplicationLaid-Open No. 2000-232216 (corresponding to EP1017106A).

The present inventor has found that, in the above described CMOS sensorhaving a shared-transistor configuration disclosed in Japanese PatentApplication Laid-Open No. H09-046596, a sensitivity difference betweenpixels is more likely to arise relative to the CMOS sensor having anon-shared-transistor configuration disclosed in Japanese PatentApplication Laid-Open No. H11-122532.

An object of the present invention is to prevent the sensitivitydifference while realizing miniaturization by a shared-transistorconfiguration.

SUMMARY OF THE INVENTION

The present inventor has found that, in a CMOS sensor having ashared-transistor configuration, a sensitivity difference between pixelsis more likely to arise relative to a CMOS sensor having anon-shared-transistor configuration, and that the reason for this liesin translational symmetry of a photodiode and shared transistor,especially of a photodiode and transfer MOS transistor.

Specifically, in the CMOS sensor having a shared-transistorconfiguration, translational symmetry with respect to the position ofshared transistors has not been taken into consideration. In JapanesePatent Application Laid-Open No. 2000-232216 in which an exemplary pixellayout of a shared-transistor configuration is disclosed, a single rowselection switch and a single reset switch are shared by plural pixels.Consequently, the relative position observed from each pixel whichshares the switch is not symmetrical; accordingly, it does not havetranslational symmetry. Further, in the same patent application, thereis no translational symmetry for the transfer switch, either.

The present inventor has found that when translational symmetry in thelayout (especially, photodiode and transfer MOS transistor) within theunit cell is lost, a characteristic difference between pixels can arise,and a characteristic difference of charge transfer from the photodiodeis especially likely to arise; thus, when there is a difference in thealignment of the active region and gate, a difference in the fringeelectric field from the gate can arise, thus producing a sensitivitydifference. Even when there is a difference in the alignment of theactive region and gate, if translational symmetry is maintained, thedifference arises in the same way for each pixel; thus a sensitivitydifference hardly arises.

The present invention was made in view of the above-described technicalbackground to provide a solid state imaging device having disposedtherein a plurality of unit cells including: a plurality ofphotoelectric conversion regions; a plurality of transfer switch meansprovided corresponding to the plurality of photoelectric conversionregions, respectively; and common amplification means which amplifiesand outputs signals read from the plurality of photoelectric conversionregions, wherein each pair within the unit cell, composed of thephotoelectric conversion region and the transfer switch means providedcorresponding to the photoelectric conversion region, has translationalsymmetry with respect to one another.

Here, the term “translational symmetry” means that, when a pair ofphotoelectric conversion region and transfer switch moves in parallel inan identical direction by a given interval (pixel pitch, i.e., pitch ofphotoelectric conversion region), the pair of photoelectric conversionregion and transfer switch coincides with another pair of photoelectricconversion region and transfer switch.

According to another aspect of the present invention, there is providedan imaging device having disposed therein a plurality of unit cellsincluding: a plurality of photoelectric conversion regions; a pluralityof floating diffusion regions provided corresponding to the plurality ofphotoelectric conversion regions, respectively; a plurality of MOStransistors for transferring signal charges of the photoelectricconversion region to the floating diffusion region; and commonamplification means which amplifies and outputs signals read from theplurality of photoelectric conversion regions, wherein each of thephotoelectric conversion regions is disposed at a first pitch; each ofthe MOS transistor gate electrodes is disposed at a second pitch; eachof the floating diffusion regions is disposed at a third pitch; and thefirst, second and third pitches are equal to each other.

Other features and advantages of the present invention will be apparentfrom the following description taken in conjunction with theaccompanying drawings, in which like reference characters designate thesame or similar parts throughout the figures thereof.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a plan view showing a layout of a unit cell of a solid stateimaging device according to a first embodiment of the present invention;

FIG. 2 is an equivalent circuit diagram of the solid state imagingdevice according to the first embodiment of the present invention;

FIG. 3 is a drive pulse timing chart of the solid state imaging deviceaccording to the first embodiment of the present invention;

FIG. 4 is a drive pulse timing chart of the solid state imaging deviceaccording to the first embodiment of the present invention;

FIG. 5 is an equivalent circuit diagram of a solid state imaging deviceaccording to a second embodiment of the present invention;

FIG. 6 is a plan view showing a layout of a unit cell of the solid stateimaging device according to the second embodiment of the presentinvention;

FIG. 7 is a plan view showing a layout of a unit cell of a solid stateimaging device according to a third embodiment of the present invention;

FIG. 8 is a view showing an insulating gate type transistor connected inparallel;

FIG. 9 is a plan view showing a layout of a unit cell of a solid stateimaging device according to a fourth embodiment of the presentinvention;

FIG. 10 is a plan view showing a color filter configuration of a solidstate imaging device according to the fourth embodiment of the presentinvention;

FIG. 11 is a conceptual view showing an imaging system according to afifth embodiment of the present invention; and

FIG. 12 is an equivalent circuit diagram of a solid state imaging deviceof conventional art.

The accompanying drawings, which are incorporated in and constitute apart of the specification, illustrate embodiments of the invention and,together with the description, serve to explain the principles of theinvention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Embodiments of the present invention will be described below in detail.

Embodiment 1

An imaging device according to a first embodiment of the presentinvention will be described. FIG. 1 is a plan view of a unit cell of animaging device according to the first embodiment. FIG. 2 is anequivalent circuit diagram of the imaging device according to thepresent embodiment, in which pixels having the layout shown in FIG. 1are disposed two-dimensionally.

In FIG. 2, the unit cell includes photodiodes 101A and 101B being aphotoelectric conversion element, and a common amplification MOSFET 104which amplifies signals generated in the photodiodes 101A and 101B, andfurther, a reset MOSFET 103 acting as a common reset switch which resetsthe input of the amplification MOSFET 104 to a predetermined voltage,and a row selecting MOSFET 105 acting as a common row selecting switchwhich controls conduction between the source electrode of theamplification MOSFET 104 and a vertical output line 106. In addition,transfer MOSFET 102A and MOSFET 102B acting as a transfer switch areprovided corresponding to the photodiodes 101A and 101B, respectively.Here, two photodiodes are formed in the unit cell; therefore the unitcell includes two pixels.

In FIG. 1, reference numerals 101A and 101B denote N type diffusionregions disposed in a P well (a P well and N type diffusion regionconstitute a PN junction); 104 the gate electrode of the amplificationMOSFET; 103 the gate electrode of the reset MOSFET; 105 the gateelectrode of the row selecting MOSFET; 102A and 102B the gate electrodesof the transfer MOSFETs; 130 an N type dopant region connected to anelectric power source (VDD); 131 a P type dopant region (well contact)connected to the ground.

Charges accumulated in the photodiodes 101A and 101B are transferred toeach floating diffusion region 132 via the transfer MOSFETs 102A and102B, respectively. Each of the floating diffusion regions 132 areconnected to the gate electrode of the amplification MOSFET 104 and thesource electrode of the reset MOSFET 103 via a wire 133 in a sharedmanner. As evident from FIG. 1, the relative position between thetransfer MOSFETs 102A and 102B and the photodiodes 101A and 101B hastranslational symmetry. In the transfer MOSFETs 102A and 102B, part ofthe N type diffusion regions 101A and 101B acts as the source regionthereof, and the floating diffusion region 132 acts as the drain regionthereof. If a pair of the photoelectric conversion region and transferswitch has translational symmetry, this means that, when the N typediffusion region 101A of the photodiode, the gate electrode of thetransfer MOSFET 102A and the floating diffusion region acting as thedrain region of the transfer MOSFET 102A move in a direction of row by apixel pitch, they coincide with the N type diffusion region 101B of thephotodiode, the gate electrode of the transfer MOSFET 102B and thefloating diffusion region acting as the drain region of the pixeltransfer MOSFET 102B, respectively. Accordingly, it can also be saidthat each of the photoelectric conversion regions is disposed at a firstpitch; each of the transfer MOSFET gate electrodes is disposed at asecond pitch; each of the floating diffusion regions is disposed at athird pitch; the first, second and third pitches are equal to eachother.

Accordingly, when the transfer MOSFET 102A and photodiode 101A are movedin parallel by a pixel pitch, the transfer MOSFET 102A and photodiode101A coincide with the transfer MOSFET 102B and photodiode 101B. Bydisposing the components in this way so as to have translationalsymmetry, a systematic difference of transfer characteristics isprevented from arising, whereby a sensitivity difference can beprevented.

The photodiodes 101A is disposed in an odd number row, and thephotodiode 101B is disposed in an even number row; this disposition isrepeated, thereby constituting an area sensor. The transfer MOSFET 102Ais driven by transfer pulse PTX1, and the transfer MOSFET 102B is drivenby transfer pulse PTX2. The reset MOSFET 103 being shared is driven byreset pulse PRES. The row selecting MOSFET 105 is driven by rowselecting pulse PSEL.

The operation of the imaging device will be described with reference todrive pulse timing charts of FIGS. 3 and 4. Assume that, before a readoperation, a predetermined time period of exposure has elapsed, wherebyphoto charges have been accumulated in the photodiodes 101A and 101B. Asshown in FIG. 3, firstly pixel reset pulse PRES is changed from a highlevel to a low level with respect to a row selected by a verticalscanning circuit 123, whereby the reset of the gate electrode of theamplification MOSFET 104 is released. At this time, a voltagecorresponding to a dark state is held in a capacitor (hereinafterreferred to as Cfd) of the floating diffusion region connected to thegate electrode. Subsequently, when row selecting pulse PSEL becomes ahigh level, the output in a dark state is introduced onto a verticaloutput line 106. At this time, the operational amplifier 120 is in avoltage follower state, and the output of the operational amplifier 120is approximately equal to a reference voltage VREF. After apredetermined time period elapses, clamp pulse PC0R is changed from ahigh level to a low level, whereby the output in a dark state on thevertical output line 106 is clamped. Subsequently, pulse PTN becomes ahigh level, and the transfer gate 110A is turned on, whereby the darksignal, including an offset of the operational amplifier 120, is storedin a holding capacitance 112A. Then the transfer MOSFET 102A is made ahigh level by transfer pulse PTX1 for a predetermined time period,whereby the photo charges accumulated in the photodiode 101A aretransferred to the gate electrode of the amplification MOSFET 104.Meanwhile, the transfer MOSFET 102B, kept at a low level, is in awaiting state with the photo charges of the photodiode 110B being held.Here, when the transfer charge is an electron and Q is the absolutevalue of the amount of transferred charges, the gate potential isreduced by Q/Cfd. In response to this, an output in a bright state isintroduced onto the vertical output line 106. When Gsf is the sourcefollower gain, variation ΔVv1 of vertical output line potential Vv1relative to the output in a dark state is expressed as the followingformula. $\begin{matrix}{{\Delta\quad{Vvl}} = {{- \frac{Q}{Cfd}} \cdot {Gsf}}} & \lbrack {{Formula}\quad 1} \rbrack\end{matrix}$

This potential variation is amplified by an inverting amplifier composedof the operational amplifier 120, a clamp capacitor 108 and feedbackcapacitor 121. In combination with formula 1, output Vct is expressed asthe following formula. $\begin{matrix}{{Vct} = {{VREF} + {\frac{Q}{Cfd} \cdot {Gsf} \cdot \frac{C0}{Cf}}}} & \lbrack {{Formula}\quad 2} \rbrack\end{matrix}$where C0 indicates clamp capacitance, and Cf indicates feedbackcapacitance. The output Vct is stored in another holding capacitor 112Bduring a time period when pulse PTS becomes a high level and thetransfer gate is in the ON state. Subsequently, horizontal transferswitches 114B and 114A are sequentially selected by scanning pulses H1,H2 . . . generated by a horizontal shift register 119, whereby thesignals held at the accumulation capacitors 112B and 112A are read outonto horizontal output lines 116B and 116A, and then supplied to anoutput amplifier 118 to be outputted as a differential signal. In theoperation described until now, a read operation for one odd number rowin which the photodiode 101A is disposed is completed.

Subsequently, a read operation approximately similar to that for the oddnumber row is repeated for the photodiode 101B of the even number row.The difference from the odd number row is that, as shown in FIG. 4,transfer pulse PTX2 instead of transfer pulse PTX1 becomes a high level,whereby the transfer MOSFET 102B is turned on. At the time when theoperation of reading photo charges of the photodiode 101B disposed inthe even number row is terminated, pixel outputs for two rows have beenread; this operation is repeatedly performed for the entire image plane,thereby outputting one picture image. In an imaging device having a unitcell composed of two pixels, shown in FIG. 4 of Japanese PatentApplication Laid-Open No. 2000-232216, which does not have translationalsymmetry, there is no translational symmetry in the photodiode andtransfer MOSFET. Consequently, a difference arises between the amount ofcharges read from one photodiode of the unit cell and that read from theother photodiode. Thus the optical output of odd number row is differentfrom that of even number row, creating periodical noises to deterioratethe picture quality. With the imaging device according to the presentembodiment of the present invention, however, such periodical noises arenot created, whereby a satisfactory picture image can be obtained.

Translational symmetry within a unit cell is described here. However,needless to say, unit cells neighboring each other in row and columndirections have translational symmetry with one another with respect tounit cell pitch.

Embodiment 2

An imaging device according to a second embodiment of the presentinvention will be described. FIG. 5 is an equivalent circuit diagram ofan imaging device according to the second embodiment, in which oneportion relating to 2×4 pixels selected from among pixels arrangedtwo-dimensionally is shown. In the imaging device according to thepresent embodiment, four pixels, sharing an amplification MOSFET, resetMOSFET and row selecting MOSFET, constitute a unit cell. FIG. 6 is aplan view showing a layout of these pixels. In FIGS. 5 and 6, the samereference numerals are applied to constituent components correspondingto FIGS. 2 and 1, and hence repeated explanation thereof is omitted. Theshape of the gate electrode of a transfer MOSFET of FIG. 6 is apparentlydifferent from that of the gate electrode of a transfer MOSFET ofFIG. 1. However, this is due to simplification; actually the shape ofthe gate electrode of a transfer MOSFET of FIG. 6 is identical to thatof the gate electrode of a transfer MOSFET of FIG. 1 (the same appliesto Embodiments 3 and 4).

In FIG. 6, reference numerals 101A to 101D denote N type diffusionregions of photodiodes disposed in P wells (a P well and N typediffusion region constitute a PN junction); reference numerals 102A to102D denote the gate electrodes of transfer MOSFETs.

A reset MOSFET 103, amplification MOSFET 104 and row selecting MOSFET105 are shared by four pixels, and photodiodes 101A, 101B, 101C and 101Dare disposed in lines 4 n-3, 4 n-2, 4 n-1 and 4 n, respectively (n beinga natural number). A transfer MOSFETs 102A, 102B, 102C and 102D arearranged in equivalent positions relative to the photodiodes 101A, 101B,101C and 101D, respectively, thus having translational symmetry.Consequently, a sensitivity difference between the four pixels isreduced. The number of transistors within a unit cell is 7; the numberof transistors per pixel is 1.75. This is advantageous in reducing pixelsize. In an imaging device without translational symmetry, when afour-pixel shared transistor configuration is employed, fixed-patternnoises having a period of four rows caused by a sensitivity differenceare generated in many cases. With the imaging device of the presentembodiment, such periodical noises are not generated; thus asatisfactory picture image can be obtained.

Embodiment 3

An imaging device according to a third embodiment of the presentinvention will be described. The equivalent circuit of an imaging deviceaccording to the third embodiment is similar to that of the secondembodiment. FIG. 7 is a plan view showing a layout of the pixels. InFIG. 7, the same reference numerals are applied to constituentcomponents corresponding to FIG. 6, and hence repeated explanationthereof is omitted. A reset MOSFET 103, amplification MOSFET 104 and rowselecting MOSFET 105 are shared by four pixels, and photodiodes 101A,101B, 101C and 101D are disposed in lines 4 n-3, 4 n-2, 4 n-1 and 4 n,respectively (n being a natural number). A transfer switches 102A, 102B,102C and 102D are arranged in equivalent positions relative to thephotodiodes 101A, 101B, 101C and 101D, respectively, thus havingtranslational symmetry. Consequently, a sensitivity difference betweenthe four pixels does not arise. A feature of the imaging device of thepresent embodiment is that, as shown in FIG. 8, in the reset MOSFET 103,amplification MOSFET 104 and row selecting MOSFET 105, two MOSFETs eachbeing an unit element is connected in parallel to each other.Accordingly, a gate width being effectively twice that of Embodiment 2is obtained. Consequently, a restraint arises in the minimal size of atransistor; this is slightly less advantageous in the reduction of sizeof a pixel than an imaging device of the second embodiment. However, thedrive force of a MOSFET is raised, whereby a more high speed pixel readoperation becomes possible. While fixed-pattern noises having a periodof four rows caused by a sensitivity difference are generated in animaging device without translational symmetry, such periodical noisescan be reduced in the imaging device of the present embodiment similarlyto the imaging device of the second embodiment, whereby a satisfactorypicture image can be obtained.

The gate electrodes of two reset switches 103 and the gate electrodes oftwo row selecting switches 105 are connected to common drive lines,respectively.

Embodiment 4

An imaging device according to a fourth embodiment of the presentinvention will be described. The equivalent circuit of an imaging deviceaccording to the fourth embodiment is similar to that of the second andthird embodiments. FIG. 9 is a plan view showing a layout of the pixels.In FIG. 9, the same reference numerals are applied to constituentcomponents corresponding to FIG. 1, and hence repeated explanationthereof is omitted. A reset MOSFET 103, amplification MOSFET 104 and rowselecting MOSFET 105 are shared by four pixels, and photodiodes 101A,101B, 101C and 101D are disposed so that a unit cell is formed in arectangular shape of 2×2. As shown in FIG. 10, a color filterconfiguration of bayer arrangement is employed in which green filtersare arranged in a checkered pattern. In FIG. 10, reference, charactersGb and Gr each denote a green filter; B a blue filter; R a red filter.Accordingly, even when the capacitance of a floating diffusion region132 to which four pixels are connected in a shared manner varies, oreven when the amplification gain of a common amplification MOSFET 104varies, since the gain within a picture element varies by the sameratio, the color ratio within the picture element does not vary. Atransfer MOSFET 102A, MOSFET 102B, MOSFET 102C and MOSFET 102D arearranged in equivalent positions relative to the photodiodes 101A, 101B,101C and 101D, respectively, thus having translational symmetry.Accordingly, there does not arise a sensitivity difference between thephotodiodes 101B and 101C corresponding to filters Gr and Gb whichshould have the same color and the same sensitivity. Consequently, whileperiodical fixed-pattern noises caused by a sensitivity difference aregenerated in an imaging device without translational symmetry, suchperiodical noises are not generated reduced in the imaging device of thepresent embodiment, whereby a satisfactory picture image can beobtained.

Embodiment 5

FIG. 11 is a configuration diagram of an imaging system using theimaging device according to each of the above described embodiments. Theimaging system includes a barrier 1001 which doubles as a lens protectand main switch; a lens 1002 which focuses the optical image of anobject on an image sensor 1004; an aperture 1003 which varies the amountof light passing through the lens 1002; and further, the image sensor1004 (corresponding to the imaging device described in each of the abovedescribed embodiments) which imports an object focused by the lens 1002as an image signal; an image signal processing circuit 1005 whichprocesses an image signal outputted from the image sensor 1004 forvarious corrections, clamping, and so on.; an A/D converter 1006 whichconverts the image signal outputted from the image sensor 1004 fromanalog to digital form.; a signal processing section 1007 which performsvarious corrections and data compression on an image data outputted fromthe A/D converter 1006; and a timing generation section 1008 whichoutputs various timing signals to the image sensor 1004, image signalprocessing circuit 1005, A/D converter 1006 and signal processingsection 1007. Each of the circuits 1005 to 1008 may be formed on thesame chip as the solid state image sensor 1004. The imaging system alsoincludes an overall-control and arithmetic processing section 1009 whichperforms various arithmetic processings and controls the entire stillvideo camera; a memory section 1010 which temporarily stores image data;a recording medium control interface section 1011 for recording orreading data onto/from a recording medium; a detachable recording medium1012, such as a semiconductor memory, for recording or reading imagedata; and an external interface (I/F) section 1013 for communicatingwith an external computer or the like.

The operation of FIG. 11 will now be described. When the barrier 1001 isopened, the main switch is turned on. Subsequently, the electrical powersource of the control system is turned on, and further the electricalpower sources of the imaging system circuits, such as the A/D converter1006, are turned on. Then, in order to control the light exposure, theoverall-control and arithmetic processing section 1009 opens theaperture 1003; a signal outputted from the image sensor 1004 isoutputted directly to the A/D converter 1006 via the image signalprocessing circuit 1005. The A/D converter 1006 converts the signal andoutputs the resultant signal to the signal processing section 1007.Based on the data, the signal processing section 1007 causes theoverall-control and arithmetic processing section 1009 to perform theexposure calculation.

The brightness is determined from the photometry result, and theoverall-control and arithmetic processing section 1009 controls theaperture according to the determination result. Subsequently, based onthe signal outputted from the image sensor 1004, high-frequencycomponents are extracted, and the distance to the object is calculatedby the overall-control and arithmetic processing section 1009. Then thelens 1002 is driven to determine whether or not it is in focus; if it isdetermined that it is out of focus, the lens 1002 is driven again toperform ranging.

After it is confirmed that it is in focus, the real exposure isinitiated. After the exposure is completed, an image signal outputtedfrom the image sensor 1004 is subjected to corrections, etc. in theimage signal processing circuit 1005, and converted from analog todigital form by the A/D converter 1006, and got through the signalprocessing section 1007, and stored in the memory section 1010 by theoverall-control and arithmetic processing section 1009. Then the datastored in the memory section 1010 is recorded through the recordingmedium control interface (I/F) section 1011 onto a detachable recordingmedium 1012, such as a semiconductor memory, under the control of theoverall-control and arithmetic processing section 1009. Alternatively;the data may be supplied directly to a computer or the like via theexternal interface (I/F) section 1013 to be subjected to imageprocessing.

The present invention relates to an imaging device for use in a solidstate imaging system such as a scanner, video camera and digital stillcamera.

This application claims priority from Japanese Patent Application No.2004-254358 filed on Sep. 1, 2004, which is hereby incorporated byreference herein.

1. An imaging device having disposed therein a plurality of unit cells,an each unit cell comprising: a plurality of photoelectric conversionregions; a transfer means arranged corresponding to the plurality ofphotoelectric conversion regions, respectively; and common amplificationmeans which amplifies signals transferred from the plurality ofphotoelectric conversion regions, wherein each pair within the unitcell, composed of the photoelectric conversion region and the transfermeans provided corresponding to the photoelectric conversion region,arranged translational symmetry with respect to one another.
 2. Theimaging device according to claim 1, wherein reset means which resets aninput of the amplification means is included in the unit cell.
 3. Theimaging device according to claim 1, wherein selection means whichswitches between selection and non-selection of the output of theamplification means is included in the unit cell.
 4. The imaging deviceaccording to claim 1, further comprising floating diffusion regionsprovided corresponding to each of the photoelectric conversion regions,wherein the floating diffusion regions are connected by conductivematerials.
 5. The imaging device according to claim 1, wherein theamplification means, having a plurality of unit elements connected inparallel to each other, is constructed as one unit of amplificationmeans.
 6. The imaging device according to claim 2, wherein the resetmeans, having a plurality of unit elements connected in parallel to eachother, is constructed as one unit of reset means.
 7. The imaging deviceaccording to claim 3, wherein the selection switch means, having aplurality of unit elements connected in parallel to each other, isconstructed as one unit of selection switch means.
 8. The imaging deviceaccording to claim 5, wherein the unit element is an insulating gatetype transistor.
 9. The imaging device according to claim 1, furthercomprising a color filter having combined therein plural kinds offilters having spectral transmission factors different from each otherwith respect to incident light, wherein the period at which the unitcell is disposed coincides with the period at which the color filter isdisposed.
 10. The imaging device according to claim 9, wherein the colorfilter has bayer arrangement.
 11. An imaging device having disposedtherein a plurality of unit cells, an each unit cell comprising: aplurality of photoelectric conversion regions; a plurality of floatingdiffusion regions provided corresponding to the plurality ofphotoelectric conversion regions, respectively; a MOS transistor fortransferring signal charges of the photoelectric conversion region tothe floating diffusion region; and common amplification means whichamplifies signals transferred from the plurality of photoelectricconversion regions, wherein each of the photoelectric conversion regionsis disposed at a first pitch; each of the MOS transistor gate electrodesis disposed at a second pitch; each of the floating diffusion regions isdisposed at a third pitch; and the first, second and third pitches areequal to each other.
 12. An imaging system comprising: the imagingdevice according to claim 1; an optical system which focuses light onthe imaging device; and a signal processing circuit which processes anoutput signal from the imaging device.